Design of arbitrarily shaped acoustic cloaks through PDE-constrained optimization satisfying sonic-metamaterial design requirements

TL;DR

This paper presents a PDE-constrained optimization framework for designing arbitrarily shaped acoustic cloaks with simple isotropic microstructures, overcoming limitations of traditional transformation-based methods.

Contribution

It introduces a nonlinear optimal control approach that integrates microstructure design and material property optimization for acoustic cloaks.

Findings

Successful cloaking of a ship silhouette demonstrated.

Optimized cloaks perform well across various frequencies and incident directions.

The method simplifies microstructure complexity for practical implementation.

Abstract

We develop an optimization framework for the design of acoustic cloaks, with the aim of overcoming the limitations of usual transformation-based cloaks in terms of microstructure complexity and shape arbitrarity of the obstacle. This is achieved by recasting the acoustic cloaking design as a nonlinear optimal control problem constrained by a linear elliptic partial differential equation. In this setting, isotropic material properties' distributions realizing the cloak take the form of control functions and a system of first-order optimality conditions is derived accordingly. Such isotropic media can then be obtained in practice with simple hexagonal lattices of inclusions in water. For this reason, the optimization problem is directly formulated to take into account suitable partitions of the control domain Two types of inclusions are considered, and long-wavelength homogenization is used to define the feasible set of material properties that is employed as a constraint in the optimization problem. In this manner, we link the stage of material properties optimization with that of microstructure design, aiming at finding the optimal implementable solution. As a test benchmark, cloaking of the silhouette of a ship is considered, for various frequencies and directions of incidence. The resulting cloak is numerically tested via coupled structural/acoustic simulations.